DE10321207B3 - Method for controlling the transmission power of a transmitting station of a radio communication system and transmitting station, receiving station and radio communication system - Google Patents

Abstract

In a method of controlling transmission power of a transmitting station (UE) of a radio communication system, a receiving station (NodeB1, NodeB2) receives data packets (D1, D2, D3, D4) from the transmitting station (UE), receives the receiving station (NodeB1, NodeB2 ) not correctly received data packets (D1, D2) again from the transmitting station (UE), the transmission power of the transmitting station (UE) is controlled in response to a repetition rate of the data packets received again by the receiving station.

Description

The The invention relates to a method for controlling the transmission power a transmitting station of a radio communication system and a corresponding transmitting station, a corresponding receiving station and a corresponding radio communication system.

Around in radio communication systems, for example, according to the UMTS standard (UMTS: Universal Mobile Telecommunication System), a faultless data transmission for all to be transferred Will allow data packets a method used by a receiving station incorrectly received data packets are received again. These Procedure is under its English name "Automatic Repeat request "(ARQ) known.

Receives one receiving station, for example a base station, a data packet not correct, d. H. the data packet can not be decoded properly be signaled to a sending station, for example a subscriber station, the faulty reception by a NACK signal (NACK: Not ACKnowledgement). The subscriber station then sends the corresponding data packet again to the base station. A correct one (error-free) reception of a data packet signals the base station by an ACK signal (ACK: ACKnowledgement).

switches the subscriber station in another radio cell, it enters the transmission and reception range of at least one further base station. In the case of a so-called soft handover sends the subscriber station at the same time data packets to the base station the original one Cell and at least one other base station of the new cell. All data packets received by the base stations are sent to a Radio access controller (Radio Network Controller [RNC]) forwarded and evaluated there. In the radio access controller, the correctly received Packaged data packets in the correct order and the same data packets are combined.

The Subscriber station receives while a soft handover from the at least two base stations ACK- and NACK signals. A sufficient criterion for sending a new one Data packet is that the subscriber station receives an ACK signal from one of the base stations receives, since it is for a perfect data transfer sufficient that a data packet once error-free to the radio access controller is forwarded.

to warranty a desired one quality the data transmission the subscriber station becomes an error rate in the radio access controller (BER: Bit Error Rate or BLER: Block Error Rate) based on all received Data packets are determined and compared with a setpoint of the error rate. Dependent on from the result of this comparison, will be the base stations Setpoint for a reception quality, z. B. a signal-to-interference ratio (SIR: Signal to Interference Ratio). The base stations in turn each measure a reception quality for from the subscriber station received signals based on known control signals (pilot symbols) of the subscriber station and compare the respective measured value with the setpoint of the reception quality specified by the radio access controller. Depending on Result of the comparison, the subscriber station is signaled either to increase their transmit power or to humiliate. For this purpose, usually 1-bit signals, so-called TPC bits (TPC: Transmit Power Control) used. Receives the Subscriber station at least one TPC bit from one of the base stations, which demands a humiliation, it becomes its transmission power humiliate as much as possible to produce little interference at all receiving base stations. The regulation of the setpoint of the reception quality by the radio access controller is called external performance control referred to (outer loop power control), while the comparatively fast control the transmission power of the subscriber station by the control signals the base stations is called internal power control (inner loop power control).

in the Framework of the current standardization project of the 3GPP (3rd Generation Partnership Project) proposals are currently being discussed, including the external performance regulation to relocate to the base stations. This is beneficial for one as "enhanced uplink "(see 3GPP TR25.896v0.2.0) designated high data rate data transmission of a subscriber station to a base station, d. H. in the upward direction (Uplink).

data packets will continue with an "enhanced uplink" to the Radio access controller forwarded and joined together. Redundant data packets will continue to be combined in the radio access controller, the all receiving base stations, the so-called "active set ", a common error rate pretends. The measurement of the actual Error rate and the comparison with the setpoint of the error rate as well Modifications to the setpoint of reception quality are now being made by the base stations even done.

The setpoint of the error rate is. Usually very small (about 10 ^-6 ), so that measuring the error rate requires such a long measurement time that even slow changes in the transmission conditions are not measurable. The setpoint of Emp The quality of the catch must therefore be set so that the desired error rate in the radio access controller is achieved even in the case of poor and rapidly changing transmission conditions.

Conduct now several base stations in soft handover simultaneously received their Data packets to the radio access controller on, it results from the setting of the setpoint of the reception quality that is described above in the radio access controller actually a lower error rate is present than by the setpoint of the error rate was specified. This is due to the fact that the error rate in the radio access controller by the forwarded by all base stations Data packets is determined and thus better than by a base station alone. The transmission power of the subscriber station is thus higher than actually needed would be and there are therefore transmitted by the subscriber station Data packets more interference than the actual one Requirements for the error rate corresponding data transmission would be necessary.

From the DE 101 42 123 A1 A method is known for transmitting data packets, in which a receiver sends a positive acknowledgment message to a sender when a data packet has been received without errors. If a data packet is received incorrectly, the receiver sends the sender a negative acknowledgment message. The receiver sends the sender a repeat message requesting a retransmission of your data packet if, despite a positive acknowledgment message sent by the receiver, no retransmission of the relevant data packet takes place.

Of the The invention is therefore based on the object, an improved method for controlling the transmission power of transmitting stations of a radio communication system specify.

These Task is with the procedure, the sending station, the receiving Station and the radio communication system according to the independent claims.

advantageous Training and developments of the invention are the subject of the dependent claims.

at the method according to the invention for controlling the transmission power of a transmitting station of a radio communication system receives one Receiving station receives data packets from the sending station, which receives the Receiving station not correctly received data packets again from the transmitting station and will transmit the transmitting power Station in dependence from a repetition rate of the receiving station again controlled received data packets. A transmission power control, taking into account the repetition rate of the re-received data packets, has the advantage that even when receiving the data packets through several receiving stations the receiving stations all the same size, namely the Repetition rate, take into account the transmission power control. The sending station sends your data packets to all recipients Stations, so that all receiving stations have the same data packets received again, d. H. consider the same repetition rate. The transmission power control is thus such that by the Repetition rate takes into account a total transmission quality can be. The transmitting power of the transmitting station can therefore be set lower on average than in a transmission power control, for example, instead of the repetition rate each a block error rate taken into account in the receiving stations. The same goes for even with a data transfer to only one receiving station. The. Transmitting power of the sending Station can be humbled; if the repetition rate is lower is considered a corresponding setpoint, even if a regulation, which takes into account a block error rate, an increase requests.

Favorable Way, data packets received for the first time are provided with an identifier, which identifies the data packets as being received for the first time. To this Way you can first sent or received data packets from retransmitted or received data packets are distinguished. An identifier, the sending station used to send it for the first time Identifying data packets is, of course, from the point of view of the receiving party Station an identifier that received the data packet as the first time features.

In one embodiment of the invention, a control signal for controlling the transmission power of the transmitting station is generated in the receiving station, wherein the control signal depends on the deviation of a reception quality of the data packets from a target value of the reception quality, and the target value of the reception quality is dependent on the repetition rate set again received by the receiving station data packets. The setpoint of the reception quality can be adjusted by taking into account the repetition rate so that on average more control signals request a transmission power reduction than would be possible with a known transmission power control, for example, instead of in dependence on the Wiederho rate depending on a block error rate.

In an alternative embodiment of the invention is in the receiving Station a preliminary Control signal for controlling the transmission power of the transmitting station generated, the provisional control signal from the deviation of a reception quality of the data packets from one Setpoint of the reception quality depends and depending from the repetition rate of the again from the receiving station received data packets, a final control signal is generated. The preliminary control signal corresponds to the previously used control signals of a known Transmission power control with internal and external power control. By the final one Control signal can average the transmission power of the transmitting station lower than taking into account only the provisional control signal, because at a repetition rate below their target value the transmission power is reduced by a corresponding final control signal can be, even if the provisional Control signal would request the opposite.

In Another alternative embodiment of the invention is the Repeat rate determined in the transmitting station.

From Advantage is for this further alternative embodiment of the invention, when the station sending a control signal of the receiving station to the controller the transmission power receives and the sending station from the comparison of the repetition rate with a setpoint of the repetition rate another transmission power is set as requested by a control signal of the receiving station. In this way, the transmitting power of the transmitting station in the Mean lower than just taking into account the received control signal, because at a repetition rate below their target value the transmission power can be reduced even if the control signal is the Request opposite.

Especially advantageous is the repetition rate of the receiving again Station received data packets either from the total number the data packets received within a predeterminable time interval and the number of data packets received for the first time or from the total number of within the predeterminable time interval of the sending station sent data packets and the number of first sent data packets.

In an advantageous embodiment the receiving station is a base station and the transmitting station a mobile station.

In an alternative advantageous embodiment is the receiving Station is a mobile station and the transmitting station is a base station.

In a preferred embodiment receives at least one more Receiving station receives data packets from the sending station, which receives the further receiving station incorrectly received data packets again from the transmitting station, the transmitting power of the transmitting Station in dependence from a repetition rate of the receiving one again from the other Station received data packets are controlled and forward the receiving Stations forward their received data packets to a control station. While a data transmission can receive the same data packets from both receiving stations so that the repetition rate for both receiving stations is equal to. The transmitting power of the transmitting station can be from both receiving stations so controlled by the repetition rate be that of both receiving stations together a specific one Repetition rate and thus a total reception quality is achieved. The receiving stations transmit the data packets to the control station For example, a radio access controller on, so are in the control station receives the data packets with the total reception quality (eg a block error rate).

A preferably low occupancy of transmission resources let yourself thereby achieve that the receiving stations only correct forward received data packets to the control station.

The Invention will be described below with reference to FIGS Embodiments explained in more detail. It demonstrate:

1 a diagram of a radio communication system according to the invention with a subscriber station, two base stations and a control station,

2 a schematic representation of data packets, the subscriber station according to 1 sends to the base stations,

3 a schematic representation of a first transmission power control for the subscriber station according to 1 .

4 a schematic representation of a second transmission power control for the subscriber station according to 1 and

5 a schematic representation of a third transmission power control for the subscriber station according to 1 ,

Same Reference numerals in the figures indicate like objects.

A transmitting station is any station that can send signals. In the following is considered a transmitting station a subscriber station. A Subscriber station is for example a mobile phone or a portable device for transmitting image and / or Audio data, for fax, short message service SMS and email dispatch and to the internet access. It is therefore a general broadcasting and / or receiving unit of a radio communication system.

When receiving station is considered below a base station, but not limited thereto to be. Of course A receiving station can also be a mobile station or any one another station with a receiving device for receiving over one Transmitted wireless connection Be signals.

The Invention may be advantageous in any radio communication systems be used. Among radio communication systems are any systems to understand in which a data transfer between stations via a Radio interface takes place. The data transmission can be both bidirectional as well as unidirectional. Radio communication systems are In particular, any mobile radio systems, for example, after GSM (Global System for Mobile Communication) or the UMTS (Universal Mobile Telecommunication System) standard. Also ad-hoc networks and future mobile radio systems for example, the fourth generation to be understood by radio communication systems become.

in the The following is the invention using the example of a mobile radio system described by the UMTS standard, but without being limited thereto.

In 1 schematically a data transmission from a subscriber station UE to a first and a second base station NodeB1, NodeB2 shown. The subscriber station UE transmits, by means of its transmitting and receiving unit SE3, first data packets D1, second data packets D2, third data packets D3 and fourth data packets D4 to the base stations NodeB1, NodeB2. The base stations NodeB1, NodeB2 receive the data packets D1, D2, D3, D4 each with a transmitting and receiving unit SE1, SE2 and try to decode the data packets D1, D2, D3, D4. If the decoding succeeds, the corresponding base station NodeB1, NodeB2 sends an acknowledgment signal ACK to the subscriber station UE. The user station UE recognizes the acknowledgment signal ACK that the corresponding data packet was received correctly, ie without errors, and then sends the next data packet. If a data packet is not correctly received (decoded) by a base station, the base station NodeB1, NodeB2 sends a corresponding request signal NACK with which it requests the retransmission of the data packet that was not received correctly and thus erroneously.

Of course you can too first several Data packets, for example the first to fourth data packets D1, D2, D3, D4, are sent before the base stations NodeB1, NodeB2 for each the received data packets each have a corresponding acknowledgment Send ACK or request signal NACK. One then speaks of that the data packets are transmitted in windows become.

The Base stations NodeB1, NodeB2 forward the errors received Data packets to a data processing unit DV of a control station RNC, for example, a radio access controller, on. While the first base station NodeB1 the first, third and fourth data packet D1, D3, D4 has received error-free and forwards it to the control station RNC, the second base station NodeB2 does not have any of the first three data packets D1 receives error-free and therefore only routes the second, third and fourth data packet D2, D3, D4 to the data processing unit DV of the control station RNC on.

In the data processing unit DV are the multiple received data packets D3, D4 combined. All correctly received data packets D1, D2, D3, D4 are evaluated based on a data packet number in the Correct order brought and an unrepresented Core network to a receiver forwarded.

The Subscriber station UE transmits the first data packets D1 a total of three times to the two base stations NodeB1, NodeB2 and receives from the second base station NodeB2 every time a request signal NACK. However, since the subscriber station UE is after the third transmission of the first data packet D1 an acknowledgment signal ACK from the first Base station NodeB1 receives it next second data packet D2, although the second base station NodeB2 the first data packet D1 has still not received error-free.

The error-free reception of the second data packet D2 is confirmed to the subscriber station UE by a corresponding acknowledgment signal ACK after the second transmission from the second base station NodeB2. In this case, the first base station NodeB1 has correctly received none of the second data packets D2. The third and fourth data pairs kete D3, D4 are received error-free by both base stations NodeB1, NodeB2 already during the first transmission.

To control the transmission power of the subscriber station UE, the base stations NodeB1, NodeB2 are informed by the control station RNC of a setpoint BLERtarget for an error rate of the received data packets and a setpoint WRtarget for a repetition rate of data packets received by the subscriber station UE. Depending on a comparison of one or both desired values with a corresponding measured variable, the base stations NodeB1, NodeB2 generate by means of a control unit P1, P2 a control signal ST1, ST2, which signals to the subscriber station UE an increase or decrease in their transmission power. The processing and application of the control signals ST1, ST2 is performed by a control unit PC of the subscriber station UE. The generation of the control signals ST1, ST2 will be described below with reference to FIG 3 and 4 described.

In order that the base stations NodeB1, NodeB2 can determine a repetition rate WR of the re-received data packets, the subscriber station UE identifies, as shown schematically in FIG 2 represented by the first to fourth data packets D1, D2, D3, D4 and on the basis of further fifth and sixth data packets D5, D6, first transmitted data packets with a corresponding identifier NP.

The time sequence of the arrival of the data packets D1, D2, D3, D4, D5, D6 at the base stations NodeB1, NodeB2 takes place in 2 from right to left.

First, will the first data packet D1, provided with a corresponding identifier NP, transferred for the first time or received from the base stations NodeB1, NodeB2. It follows one twice retransmission of the first data packet D1. The second data packet D2 becomes once for the first time with identification NP and once again transferred. The third and fourth Data packet D3, D4 are only for the first time, d. H. transmitted with identifier NP, while that fifth Transfer data packet D5 three times becomes. A transmission of the fifth Data packet D5 therefore takes place with identifier NP and two further transmissions are retransmissions and therefore have no identifier NP. The sixth data packet D6 becomes once for the first time with identifier NP and once again without identifier NP received.

The base stations NodeB1, NodeB2 count in a time interval ZI the total number of received data packets, in the sem embodiment, 12 data packets, and the number of data packets NP transmitted with data, here 6 data packets. The repetition rate WR then results from the ratio of the number of data packets received with identifier to the total number of received data packets received. In the embodiment of 2 the repetition rate is 6/12 = 0.5. Of course, the repetition rate may also be independent of the total number of received data packets, in which the repetition rate is defined as the number of data packets with identifier NP received within a selectable time interval.

3 schematically shows a first embodiment for controlling the transmission power of the subscriber station UE in response to the repetition rate WR by means of control signals ST1, which generates the first base station NodeB1. Devices with the same mode of operation are correspondingly found in the second base station NodeB2 for generating the control signals ST2.

The first base station NodeB1 receives by means of their broadcasting and Receiving unit SE1 control signals PS (pilot symbols) and data packets D from the subscriber station UE. In a first control unit K1 determines the first base station NodeB1 based on the control signals PS a reception quality SIR the data packets D, for example, a signal-to-interference ratio. In a second control unit K2 is based on the received data packets D determines a repetition rate WR of the re-received data packets. In a second comparison unit V2, the repetition rate becomes WR compared with the setpoint WRtarget the repetition rate. The Result of the comparison is used to determine a setpoint SIRtar get the reception quality the data packets. In a first comparison unit V1, the reception quality SIR of the data packets compared with their setpoint SIRtarget. Is the reception quality SIR better (bigger) than the setpoint SIRtarget the reception quality (SIR> SIRtarget), it is from the comparison unit V1 generates a control signal ST1 that the subscriber station UE to lower their transmission power prompts. The control signal ST1 demands an increase if the reception quality SIR is less than your target SIRtarget.

is For example, the repetition rate WR smaller than their target value WRtarget, it follows that the transmission power of the subscriber station UE is too high and the setpoint SIRtarget the reception quality is lowered. If the repetition rate WR is greater than its setpoint WRtarget, so is the transmission power of the subscriber station UE too low and the setpoint SIRtarget of the reception quality is increased.

According to the invention, to set the target value SIRtarget of the reception quality instead of the hitherto known use of an error rate, for example a block error rate, a Repetition rate WR used again received data packets. This has the advantage that all base stations NodeB1, NodeB2 measure the same value, since the repetition rate WR is the same for all base stations NodeB1, NodeB2. In the data processing unit DV of the control station RNC, the quality of the data transmission that is required or desired is thus achieved without the subscriber station using an unnecessarily high transmission power for this purpose. The transmission power of the subscriber station UE is on average lower than in the case of known transmission power control methods. This results in less interference.

A preferred second embodiment is disclosed in 4 shown schematically. In a known transmission power control with an inner (inner loop) and outer (outer loop) control circuit for transmission power control, the repetition rate WR of the re-received data packets is additionally taken into account.

The first base station NodeB1 receives by means of their broadcasting and Receiving unit SE2 control signals PS (pilot symbols) and data packets D from the subscriber station UE. In the first control unit K1 determines the first base station NodeB1 based on the control signals PS a reception quality SIR the data packets D, for example, a signal-to-interference ratio. In a third control unit K3 is based on the received data packets D determines a block error rate BLER of the received data packets. In a third comparison unit V3, the block error rate BLER compared with the setpoint BLERtarget of the block error rate. The result The comparison is used to define the setpoint SIRtarget reception quality the data packets. In the first comparison unit V1, the reception quality SIR becomes Data packets compared with their setpoint SIRtarget. Is the reception quality SIR better as the setpoint SIRtarget (SIR> SIRtarget), Thus, a preliminary control signal VST1 is generated by the comparison unit, this is a reduction in the transmission power of the subscriber station UE calls. The preliminary Control signal VST1 requests an increase when the reception quality SIR becomes smaller is your target set SIRtarget.

In the second control unit K2 is based on the received data packets D determines the repetition rate WR of the re-received data packets. In the second comparison unit V2, the repetition rate WR compared with the setpoint WRtarget of the repetition rate. The Result of the comparison is used to determine a final control signal ST1 for controlling the transmission power of the subscriber station UE.

• 1) WR < WRtarget und VST1 entspricht einer Sendeleistungserniedrigung
• 2) WR < WRtarget und VST1 entspricht einer Sendeleistungserhöhung
• 3) WR > WRtarget und VST1 entspricht einer Sendeleistungserniedrigung
• 4) WR > WRtarget und VST1 entspricht einer Sendeleistungsererhöhung

The final control signal ST1 results from the result of the comparison of the repetition rate WR and the setpoint WRtarget of the repetition rate and the provisional control signal VST1. There are the following combination options:

• 1) WR <WRtarget and VST1 corresponds to a transmission power reduction
• 2) WR <WRtarget and VST1 corresponds to a transmission power increase
• 3) WR> WRtarget and VST1 corresponds to a transmission power reduction
• 4) WR> WRtarget and VST1 corresponds to a transmission power increase

in the Case 1) demands the final Control signal ST1 a transmission power reduction.

in the Case 2) results from the repetition rate a transmission power reduction (a smaller transmission power causes a higher repetition rate), so that the final one Control signal ST1 requests a transmission power reduction.

in the Case 3) results from the repetition rate a transmission power increase (a higher Transmission power causes a smaller repetition rate). Depending on Default by the radio communication system, can now either the Result of the repetition rate are favored, d. H. the final control signal ST1 calls contrary to the provisional Control signal VST1 a transmission power increase or the temporary control signal VST1 is favored, d. H. the final control signal ST1 requests as well as the provisional Control signal VST1 a transmission power increase. In total, the transmission power the subscriber station UE as low as possible the latter option is preferred.

in the Case 4) demands the final Control signal ST1 a transmission power increase.

The Invention effected by in previous transmission power controls unscheduled reduction of the transmission power in case 2) that the subscriber station UE overall with a lower transmission power sends and thus generates less interference.

Especially advantageous is the transmission power control according to the invention, if the subscriber station UE to several base stations NodeB1, NodeB2 transmits data packets at the same time. Of course you can the invention for both a data transfer from the subscriber station UE to a single base station as well for one data transfer from a base station to a single subscriber station.

In a third embodiment, which is in 5 is shown schematically, the subscriber station receives control signals ST from the base station NodeB1, NodeB2 and sends data packets D to the base stations NodeB1, NodeB2. The control signals ST were generated in a known manner in the base stations NodeB1, NodeB2 by means of a conventional power control, such as when exclusive use is made of the provisional control signal VST1 4 would result.

On the basis of the data packets D sent by it, the subscriber station UE determines in a control unit K a repetition rate WR of the retransmitted data packets and compares them with the setpoint WRtarget of the repetition rate in a further control unit VV which generates a corresponding provisional control signal VST. In a third control unit V, a comparison is made with the received control signal ST, and a final control signal EST is generated according to criteria that apply to 4 correspond to the criteria described in cases 1) to 4). The final control signal EST is used to control the transmission power instead of the received control signal ST.

Of the Setpoint WRtarget of the repetition rate is the subscriber station UE from the control station RNC by means of one of the base stations NodeB1, NodeB2 communicated.

Claims (15)

Method for controlling the transmission power of a transmitting station (UE) of a radio communication system in which - a receiving one Station (NodeB1, NodeB2) Data packets (D1, D2, D3, D4, D5, D6, D) receives from the sending station (UE), The receiving station (NodeB1, NodeB2) incorrectly received data packets (D1, D2, D1, D2, D5, D6) receives again from the transmitting station (UE), - And the transmission power of transmitting station (UE) depending on from a repetition rate (WR) from the receiving one again Station (NodeB1, NodeB2) received data packets (D1, D2, D1, D2, D5, D6) is controlled. The method of claim 1, wherein the first received Data packets are provided with an identifier (NP) that contains the data packets as received for the first time. Method according to claim 1 or 2, in which - in the receiving station (NodeB1, NodeB2) a control signal (ST1, ST2) to control the transmission power of the transmitting station (UE) generated is, wherein the control signal (ST1, ST2) from the deviation of a reception quality (SIR) of the data packets (D1, D2, D3, D4, D5, D6, D) from a setpoint value (SIRtarget) the reception quality depends - and the Setpoint (SIRtarget) of the reception quality as a function of the repetition rate (WR) of the receiving station (NodeB1, NodeB2) received again Data packets (D1, D2, D1, D2, D5, D6) is set. Method according to claim 1 or 2, in which - in the receiving station (NodeB1, NodeB2) a preliminary control signal (VST1) to control the transmission power of the transmitting station (UE) generated is, the provisional Control signal (VST1) from the deviation of a reception quality (SIR) of Data packets (D1, D2, D3, D4, D5, D6, D) from a setpoint (SIRtarget) the reception quality depends - and in dependence from the repetition rate (WR) of the receiving station (NodeB1, NodeB2) (D1, D2, D1, D2, D5, D6) receive a final control signal (ST1). is produced. Method according to claim 1 or 2, wherein the repetition rate (WR) is determined in the transmitting station (UE). The method of claim 5, wherein - the sending one Station (UE) a control signal (ST) of the receiving station (NodeB1, NodeB2) receives to control the transmission power and - the sending one Station (UE) from the comparison of the repetition rate (WR) with a Setpoint (WRtarget) of the repetition rate another transmission power set as by the control signal (ST) of the receiving station (NodeB1, NodeB2) is requested. Method according to one of claims 1 to 6, wherein the repetition rate (WR) of the receiving station (NodeB1, NodeB2) received again Data packets (D1, D2, D1, D2, D5, D6) either from the total number the received within a predetermined time interval (ZI) Data packets and the number of data packets received for the first time or from the total number within the predeterminable time interval (ZI) from the transmitting station (UE) sent data packets and the Number of data packets sent for the first time. Method according to one of the preceding claims, in the receiving station has a base station and the transmitting station is a mobile station. Method according to one of claims 1 to 7, wherein the receiving Station is a mobile station and the transmitting station is a base station is. Method according to one of the preceding claims, in which - at least one further receiving station (NodeB1, NodeB2) receives data packets (D1, D2, D3, D4, D5, D6; D) from the transmitting station (UE), - the further receiving station (NodeB1, NodeB2) does not receive correctly received data packets (D1, D2, D1 , D2, D5, D6) again receives from the transmitting station (UE), - the transmitting power of the transmitting station (UE) in response to a repetition rate (WR) of the data packets (D1 , D2, D1, D2, D5, D6) - and the two receiving stations (NodeB1, NodeB2) forward their received data packets to a control station (RNC). The method of claim 10, wherein the receiving Stations (NodeB1, NodeB2) only correctly received data packets forward to the control station (RNC). Receiving station (NodeB1, NodeB2) for a radio communication system With - funds (SE1, SE2) for receiving data packets (D1, D2, D3, D4, D5, D6; D) from a transmitting station (UE), - means (SE1, SE2) for renewed Reception of incorrectly received data packets (D1, D2, D1, D2, D5, D6) from the transmitting station (UE), - and with Means (P1, P2) for controlling the transmission power of the transmitting station (UE) depending on a repetition rate (WR) from the transmitting station again (UE) received data packets (D1, D2, D1, D2, D5, D6). Broadcasting Station (UE) for a radio communication system With - funds (SE3) for sending data packets (D1, D2, D3, D4, D5, D6, D) a receiving station (NodeB1, NodeB2), - means (SE3) to renew Send incorrectly from the receiving station (NodeB1, NodeB2) received data packets (D1, D2, D1, D2, D5, D6), - and with Means (PC) for controlling the transmission power of the transmitting station (UE) depending from a repetition rate (WR) which again to the receiving station (NodeB1, NodeB2) data packets (D1, D2, D1, D2, D5, D6). Radio communication system with a transmitting station (UE) with - funds (SE3) for sending data packets (D1, D2, D3, D4, D5, D6, D) a receiving station (NodeB1, NodeB2), - means (SE3) to renew Send incorrectly from the receiving station (NodeB1, NodeB2) received data packets (D1, D2, D1, D2, D5, D6), - and with Means (PC) for controlling the transmission power of the transmitting station (UE) depending from a repetition rate (WR) which again to the receiving station (NodeB1, NodeB2) data packets (D1, D2, D1, D2, D5, D6), and with a receiving station (NodeB1, NodeB2) with - funds (SE1, SE2) for receiving data packets (D1, D2, D3, D4, D5, D6; D) from the transmitting station (UE), - means (SE1, SE2) for renewed Reception of incorrectly received from the transmitting station (UE) Data packets (D1, D2, D1, D2, D5, D6), - and with means (P1, P2) for controlling the transmission power of the transmitting station (UE) as a function of a repetition rate (WR) from the transmitting station again (UE) received data packets (D1, D2, D1, D2, D5, D6). Radio communication system according to claim 14, - with at least another receiving station (NodeB1, NodeB2) with means (SE1, SE2) for receiving data packets (D1, D2, D3, D4, D5, D6, D) from the transmitting station (UE), with means (SE1, SE2) for re-transmission Reception of incorrectly received from the transmitting station (UE) Data packets (D1, D2, D1, D2, D5, D6) and means (P1, P2) for Controlling the transmission power of the transmitting station (UE) in dependence from a repetition rate (WR) from the sending station again (UE) received data packets (D1, D2, D1, D2, D5, D6), - whose receiving stations (NodeB1, NodeB2) each means (SE1, SE2) for forwarding the received data packets to a control station (RNC).